First evidence of frugivory in <i>Gardnerycteris crenulatum</i> (Chiroptera: Phyllostomidae)

CASTILLO-FIGUEROA, Dennis; TARRÁ-JARAMILLO, Bryan A.; PEÑUELA-SALGADO, Mónica M.; GIRALDO-MARTÍNEZ, Carlos A.; RODRÍGUEZ-LEÓN, Carlos H.

doi:10.1590/1809-4392202102151

ABSTRACT

Gardnerycteris crenulatum is a bat species restricted to South America, being particularly rare in lowland rainforests. It is characterized by a diet composed mainly of arthropods and small vertebrates, with no confirmed evidence of fruit consumption. Here, we provide the first records of seeds in the diet of G. crenulatum. The seeds were found in the feces of two individuals captured in late-successional forests in the Colombian Amazon (one pregnant female and one adult male), that belonged to Piper sp. (n = 125) and Cecropia engleriana (n = 3). In germination experiments, only Piper seeds germinated (8%). Insectivores can potentially perform other functions than the role assigned to their corresponding guild. More research is needed on the natural history and ecology of G. crenulatum to elucidate its possible role as seed disperser.

KEYWORDS:
Amazon rainforest; bats; functional role; diet; insectivores

RESUMEN

Gardnerycteris crenulatum es una especie de murciélago restringida a América del Sur, siendo particularmente rara en los bosques húmedos de tierras bajas. Se caracteriza por una dieta compuesta principalmente de insectos, artrópodos y pequeños vertebrados, sin evidencia confirmada de consumo de frutos. En esta nota, reportamos los primeros registros de semillas en la dieta de G. crenulatum. Las semillas fueron encontradas en las fecas de dos individuos capturados en bosques de sucesión avanzada en la Amazonía colombiana (una hembra preñada y un macho adulto), pertenecientes a Piper sp. (n = 125) y Cecropia engleriana (n = 3). En experimentos de germinación, solo germinaron las semillas de Piper sp. (8%). Los insectívoros pueden realizar potencialmente otras funciones además del papel asignado a su gremio correspondiente. Es necesario desarrollar más investigaciones sobre la historia natural y la ecología de G. crenulatum para dilucidar su posible papel como dispersor de semillas.

PALABRAS CLAVE:
dieta; insectívoros; murciélagos; papel funcional; selva amazónica

Among Neotropical bats, Phyllostomidae is the most speciose family, with 225 recognized species distributed in 60 genera (ASM 2021ASM. 2021. Mammal Diversity Database, Version 1.6. American Society of Mammalogists. ( (https://www.mammaldiversity.org/taxa.html ). Accessed on 08 Oct 2021.
https://www.mammaldiversity.org/taxa.htm... ). Phyllostomids are the most ecologically diverse bat group, exhibiting a broad range of morphological traits (Norberg and Rayner 1987Norberg, U.M.; Rayner, J.M. 1987. Ecological morphology and flight in bats (Mammalia; Chiroptera): wing adaptations, flight performance, foraging strategy and echolocation. Philosophical Transactions of the Royal Society B: Biological Sciences, 316: 335-427.; Marinello and Bernard, 2014Marinello, M.M.; Bernard, E. 2014. Wing morphology of Neotropical bats: a quantitative and qualitative analysis with implications for habitat use. Canadian Journal of Zoology, 92: 141-147.; Castillo-Figueroa 2020Castillo-Figueroa, D. 2020a. Ecological morphology of neotropical bat wing structures. Zoological Studies, 59: e60. a), behavioral strategies (Kerth 2008Kerth, G. 2008. Causes and consequences of sociality in bats. Bioscience, 58: 737-746.), roosts (Voss et al. 2016Voss, R.S.; Fleck, D.W.; Strauss, R.E.; Velazco, P.M.; Simmons, N.B. 2016. Roosting ecology of amazonian bats: evidence for guild structure in hyperdiverse mammalian communities. American Museum Novitates, 3870: 1-44.; Garbino and Tavares 2018Garbino, G.S.; Tavares, V.D.C. 2018. Roosting ecology of Stenodermatinae bats (Phyllostomidae): Evolution of foliage roosting and correlated phenotypes. Mammal Review, 48: 75-89.) and feeding habits (Wilson 1973Wilson, D.E. 1973. Bat faunas: a trophic comparison. Systematic Zoology, 22: 14-29.). Food items consumed by phyllostomids include fruits, nectar, insects and other arthropods, vertebrates and blood, but some species can complement their diet by consuming uncommon items (Wilson 1973). For example, bats specialized in nectar, like Leptonycteris yerbabuenae Martínez and Villa-R. 1940 and Glossophaga longirostris Miller 1898, can also feed on fruits, thus acting as seed dispersers (Nassar et al. 1997Nassar, J.M.; Ramírez, M.N.; Linares, O. 1997. Comparative pollination biology of Venezuelan columnar cacti and the role of nectar-feeding bats in their sexual reproduction. American Journal of Botany, 84: 918-927.; Soriano and Ruiz 2002Soriano, P.J.; Ruiz, A. 2002. The role of bats in reproduction of columnar cacti in the northern Andes. In: Fleming, T.H.; Valiente-Banuet, A. (Ed.). Ecology, Evolution and Conservation of Columnar Cacti and Their Mutualists (241-263). Arizona University Press, Tucson, p.241-263.; Rojas-Martínez et al. 2015Rojas-Martínez, A.E.; Pavón, N.P.; Castillo, J.P. 2015. Effects of seed ingestion by the lesser long-nosed bat Leptonycteris yerbabuenae on the germination of the giant cactus Isolatocereus dumortieri. The Southwestern Naturalist, 60: 85-89.; Santiago-Hernández et al. 2019Santiago-Hernández, M.H.; Martén-Rodríguez, S.; Lopezaraiza- Mikel, M.; Oyama, K.; González-Rodríguez, A.; Quesada, M. 2019. The role of pollination effectiveness on the attributes of interaction networks: from floral visitation to plant fitness. Ecology, 100: e02803.). Likewise, frugivores such as Artibeus lituratus (Olfers 1818), Carollia perspicillata (Linnaeus 1758) and Sturnira lilium (E. Geoffroy 1810) have preference for Ficus, Piper and Solanum, respectively (Fleming 1986Fleming, T.H. 1986. Opportunism versus specialization: the evolution of feeding strategies in frugivorous bats. In: Estrada, A.; Fleming, T.H. (Ed.). Frugivores and Seed Dispersal. Springer, Dordrecht, p.105-118.; Saldaña-Vázquez et al. 2019Saldaña-Vázquez, R.A.; Castaño, J.H.; Baldwin, J.; Pérez-Torres, J. 2019. Does seed ingestion by bats increase germination?: a new meta-analysis 15 years later. Mammal Review, 49: 201-209.), yet they complement their diets by consuming other fruits, nectar and insects (Giannini and Kalko 2004Giannini, N.P.; Kalko, E.K. 2004. Trophic structure in a large assemblage of Phyllostomid bats in Panama. Oikos, 105: 209-222.). However, few cases of insectivorous bats that consume plant items have been reported (Aranguren et al. 2011Aranguren, C.I.; González-Carcacía, J.A.; Martínez, H.; Nassar, J.M. 2011. Noctilio albiventris (Noctilionidae), a potential seed disperser in disturbed tropical dry forest habitats. Acta Chiropterologica, 13: 189-194.; Felix et al. 2013Felix, S.; Novaes, R.L.M.; Souza, R.F.; Santori, R.T. 2013. Diet of Tonatia bidens (Chiroptera, Phyllostomidae) in an Atlantic Forest area, southeastern Brazil: first evidence for frugivory. Mammalia, 77: 451-454. ; Novaes et al. 2015Novaes, R.; Souza, R.; Ribeiro, E.; Siqueira, A.; Greco, A.; Moratelli, R. 2015. First evidence of frugivory in Myotis (Chiroptera, Vespertilionidae, Myotinae). Biodiversity Data Journal, 3: e6841.).

Gardnerycteris (Mimon) crenulatum (Geoffroy St.-Hilaire, 1803) (Phyllostomidae) is an endemic species of South America ranging from southern Brazil and northern Bolivia to southern Panamá (Koopman 1978Koopman, K.F. 1978. Zoogeography of Peruvian bats with special emphasis on the role of the Andes. American Museum Novitates, 2651: 1-33.; Williams and Genoways 2008Williams, S.; Genoways, H. 2008. Subfamily Phyllostominae. In: Gardner, A.L. (Ed.). Mammals of South America. v.I. Marsupials, Xenarthrans, Shrews and Bats. The University of Chicago Press., Chicago, 669p.). It mainly inhabits lowland rainforests below 900 m (Tirira 2017Tirira, D.G. 2017. A Field Guide to the Mammals of Ecuador. 1st ed. Editorial Murciélago Blanco, Quito, 600p.), using tree cavities as diurnal refuges (Voss et al. 2016Voss, R.S.; Fleck, D.W.; Strauss, R.E.; Velazco, P.M.; Simmons, N.B. 2016. Roosting ecology of amazonian bats: evidence for guild structure in hyperdiverse mammalian communities. American Museum Novitates, 3870: 1-44.), showing a strong roost fidelity (Bernard and Fenton 2003Bernard, E.; Fenton, M.B. 2003. Bat mobility and roosts in a fragmented landscape in central Amazonia, Brazil. Biotropica, 35: 262-277.), and is frequently found near water, including ponds, waterholes and rivers (Mello and Pol 2006Mello, M.A.R.; Pol, A. 2006. First record of the bat Mimon crenulatum (E. Geoffroy, 1801) (Mammalia: Chiroptera) in the state of Rio de Janeiro, Southeastern Brazil. Brazilian Journal of Biology, 66: 295-299.). It has been classified as a gleaning insectivore, consuming mainly insects and spiders in the understory (Pedro et al. 1994Pedro, W.A.; Komeno, C.A.; Taddei, V.A. 1994. Morphometrics and biological notes on Mimon crenulatum (Chiroptera, Phyllostomidae). Boletim do Museu Paraense Emílio Goeldi, 10: 107-112.; Giannini and Kalko 2005Giannini, N.P.; Kalko, E.K.V. 2005. The guild structure of animalivorous leaf-nosed bats of Barro Colorado Island, Panama, revisited. Acta Chiropterologica, 7: 131-146.; Mello and Pol 2006; Hurtado et al. 2015Hurtado, N.; Sepúlveda, R.; Pacheco, V. 2015. Sexual size dimorphism of a sensory structure in a monomorphic bat. Acta Chiropterologica, 17: 75-83.; Tirira 2017), but it can also feed on small vertebrates, nectar and pollen (Pedro et al. 1994; Mello and Pol 2006). Gardnerycteris crenulatum forms small groups (Emmons and Feer 1999Emmons, L.H.; Feer, F. 1999. Mamíferos de Los Bosques Húmedos de América Tropical, una Guía de Campo. 1st ed. Editorial FAN, Santa Cruz de la Sierra, 298p.) and, despite showing no sexual size dimorphism, the leaf-nose is wider in females, with larger spears that improve the ability of echolocation of prey, to satisfy the energetic demands of nursing and pup feeding (Hurtado et al. 2015). The species is rare in bat assemblages (Mello and Pol 2006; Solari 2019Solari, S. 2019. Mimon crenulatum. The IUCN Red List of Threatened Species: e.T13560A22105694 (T13560A22105694 (https://www.iucnredlist.org/species/13560/88177260 ). Accessed on 20 Jul 2021.
https://www.iucnredlist.org/species/1356... ) and many aspects of its trophic ecology remain poorly known, such as complementary food items to its largely insectivorous diet and its potential role as seed disperser or seed predator.

During a bat survey in the Colombian Amazon, small seeds were collected from fecal samples of two individuals of G. crenulatum and germination experiments were performed to test the viability of the seeds. Here, we report the first confirmed evidence of fruit consumption by G. crenulatum, and its potential role as a seed disperser.

Fieldwork was carried out in forest fragments in different successional stages (0 to over 40 years) in the municipality of San Jose del Fragua (Caquetá, Colombia) during October and November 2018. The study region is part of the Colombian Andean-Amazonian transition characterized by two physiographic units (Montaña and Lomerío), with monomodal rainfall (June to August) and mean atmospheric temperature from 24 to 27 °C (Murcia-García et al. 2014Murcia-García, U.G.; Medina-Lozano, R.M.; Rodríguez-Rondón, J.M.; Hernández Anzola, A.M.; Herrera-Rodríguez, E.V. 2014. Monitoreo de los bosques y otras coberturas de la amazonia colombiana, a escala 1:100.000 -Datos del período 2012. 1st ed. Instituto Amazónico de Investigaciones Científicas SINCHI, Bogotá, 144p.). Field procedures followed the guidelines approved by the American Society of Mammalogists (Sikes et al. 2016Sikes, R.S.; Gannon, W.L.; The Animal Care and Use Committee of the American Society of Mammalogists. 2016. Guidelines of the American Society of Mammalogists for the use of wild mammals in research and education. Journal of Mammalogy, 97: 663-688.) and the Colombian legislation for animal protection (Estatuto Nacional para la Protección de los Animales (Law 84/1989) under a license provided by Comité de Ética, Bioética y Bienestar Animal (CEBBA) from Universidad de La Amazonia (FCA-169/19). We captured bats with mist-nets placed in the understory (0-3 m above ground). Mist-nets were opened from 18:00 to 00:00. To assess the diet of the bats, we collected feces of captured individuals, which were kept in cotton bags for 30 min. Fecal samples were stored in individually labeled Eppendorf tubes. In the laboratory, we processed the fecal samples to separate food items. Identified seeds were classified into morphospecies. For the germination experiments, seeds were kept in Petri dishes on absorbent paper that was humidified with distilled water every second day for up to 60 days. A germination chamber with constant light was used when possible, or the seeds were placed close to a window thus receiving indirect natural light under ambient temperature (25 to 28 °C). A fungicide (Vitavax) was employed to prevent fungal growth.

We found seeds in feces of two individuals of G. crenulatum captured in late-successional forests of > 40 years. The first was an adult female with an advanced pregnancy, captured on 29 October 2018 in Montaña (1º19’19.10”N, 76º0’17.40”W). Its feces contained 125 seeds of Piper sp., each measuring 1 mm (Figure 1a). The second was an adult male captured on 24 November 2018 in Lomerio (1º11’38.4”N, 75º58’19.7”W). Its feces contained three seeds of Cecropia engleriana Snethl. measuring 2.5 mm each (Figure 1b). None of the three C. engleriana seeds germinated, while 10 (8%) of the Piper sp. seeds germinated (five seeds at 20 days and five at 40 days after sowing).

Figure 1
Individuals of Gardnerycteris crenulatum captured in an Amazon rainforest in Colombia and the seeds found in their fecal samples. A - Pregnant female and seeds of Piper sp.; B - adult male and seeds of Cecropia engleriana. Scale bars = 1 mm. This figure is in color in the electronic version.

The unexpected presence of seeds in the two fecal samples is the first evidence of fruit consumption by an insectivorous species of Gardnerycteris. There is no doubt that the seeds were in these fecal samples, as the bats were kept individually inside the bags, and the bags were cleaned after each bat captured, following Novaes et al. (2015Novaes, R.; Souza, R.; Ribeiro, E.; Siqueira, A.; Greco, A.; Moratelli, R. 2015. First evidence of frugivory in Myotis (Chiroptera, Vespertilionidae, Myotinae). Biodiversity Data Journal, 3: e6841.). As G. crenulatum is a gleaning insectivore, the accidental consumption of fruits seems unlikely.

There is increasing evidence that bats can perform multiple functions other than the role assigned to their guild (Aranguren et al. 2011Aranguren, C.I.; González-Carcacía, J.A.; Martínez, H.; Nassar, J.M. 2011. Noctilio albiventris (Noctilionidae), a potential seed disperser in disturbed tropical dry forest habitats. Acta Chiropterologica, 13: 189-194.; Frick et al. 2013Frick, W.F.; Price, R.D.; Heady, P.A.; Kay, K.M. 2013. Insectivorous bat pollinates columnar cactus more effectively per visit than specialized nectar bat. American Naturalist, 181: 137-144.; Novaes et al. 2015Novaes, R.; Souza, R.; Ribeiro, E.; Siqueira, A.; Greco, A.; Moratelli, R. 2015. First evidence of frugivory in Myotis (Chiroptera, Vespertilionidae, Myotinae). Biodiversity Data Journal, 3: e6841.; Castillo-Figueroa 2020Castillo-Figueroa, D. 2020b. Why bats matters: a critical assessment of bat-mediated ecological processes in the Neotropics. European Journal of Ecology, 6: 77-101.b). This is especially surprising in species with highly specialized diets, as is the case of insectivores that present particular morphological, physiological and behavioral adaptations to consume animal food items. Nonetheless, some studies have demonstrated that insectivorous bats can supplement their diet with plant resources, which provide high amounts of water and sugars (Felix et al. 2013Felix, S.; Novaes, R.L.M.; Souza, R.F.; Santori, R.T. 2013. Diet of Tonatia bidens (Chiroptera, Phyllostomidae) in an Atlantic Forest area, southeastern Brazil: first evidence for frugivory. Mammalia, 77: 451-454. ) and are associated with other potential functions such as pollination (Frick et al. 2013) and seed dispersal (Novaes et al. 2015). The effective performance in these functions depends on the environmental conditions and seasonality of primary trophic resources consumed, as has been previously suggested for other species (Aranguren et al. 2011; Felix et al. 2013).

Despite the low germination rate (only 8% of one of two types of seed) of seeds consumed by G. crenulatum in comparison with other insectivores that include fruits in their diet, such as Myotis nigricans (Schinz 1821) (40%) (Novaes et al. 2015Novaes, R.; Souza, R.; Ribeiro, E.; Siqueira, A.; Greco, A.; Moratelli, R. 2015. First evidence of frugivory in Myotis (Chiroptera, Vespertilionidae, Myotinae). Biodiversity Data Journal, 3: e6841.), the seeds did not seem macroscopically damaged after gut passage, maintaining their morphological integrity. This suggests that G. crenulatum can consume fruit and ingest seeds without causing any apparent damage to them, but the low germination rate suggests a limited role as an effective seed disperser. Considering that G. crenulatum is not common in bat assemblages (we captured only six individuals among 1167 captured bats = 0.51%), the potential consumption of other plant species by this bat depends on higher sampling effort. Further dietary studies will allow a better understanding of the trophic niche and the natural history of this species. The complementation of seed dispersal by dominant frugivorous bats may be a secondary ecological role of insectivorous bats.

ACKNOWLEDGMENTS

We are thankful to the Instituto Amazónico de Investigaciones Científicas -SINCHI- Sede Florencia (Caquetá, Colombia) for the economic and logistical support in the project “Restauración de áreas disturbadas por implementación de sistemas productivos agropecuarios en el departamento del Caquetá, convenio 060/2013” (Gobernación del Caquetá/Instituto SINCHI). We are also grateful to the owners of the farms who allowed us to carry out the samplings, for their kindness and hospitality. Finally, we want to thank the two reviewers and the editor for the suggestions and comments that improved the paper.

REFERENCES

Aranguren, C.I.; González-Carcacía, J.A.; Martínez, H.; Nassar, J.M. 2011. Noctilio albiventris (Noctilionidae), a potential seed disperser in disturbed tropical dry forest habitats. Acta Chiropterologica, 13: 189-194.
ASM. 2021. Mammal Diversity Database, Version 1.6. American Society of Mammalogists. ( (https://www.mammaldiversity.org/taxa.html ). Accessed on 08 Oct 2021.
» https://www.mammaldiversity.org/taxa.html
Bernard, E.; Fenton, M.B. 2003. Bat mobility and roosts in a fragmented landscape in central Amazonia, Brazil. Biotropica, 35: 262-277.
Castillo-Figueroa, D. 2020a. Ecological morphology of neotropical bat wing structures. Zoological Studies, 59: e60.
Castillo-Figueroa, D. 2020b. Why bats matters: a critical assessment of bat-mediated ecological processes in the Neotropics. European Journal of Ecology, 6: 77-101.
Emmons, L.H.; Feer, F. 1999. Mamíferos de Los Bosques Húmedos de América Tropical, una Guía de Campo 1st ed. Editorial FAN, Santa Cruz de la Sierra, 298p.
Fleming, T.H. 1986. Opportunism versus specialization: the evolution of feeding strategies in frugivorous bats. In: Estrada, A.; Fleming, T.H. (Ed.). Frugivores and Seed Dispersal Springer, Dordrecht, p.105-118.
Felix, S.; Novaes, R.L.M.; Souza, R.F.; Santori, R.T. 2013. Diet of Tonatia bidens (Chiroptera, Phyllostomidae) in an Atlantic Forest area, southeastern Brazil: first evidence for frugivory. Mammalia, 77: 451-454.
Frick, W.F.; Price, R.D.; Heady, P.A.; Kay, K.M. 2013. Insectivorous bat pollinates columnar cactus more effectively per visit than specialized nectar bat. American Naturalist, 181: 137-144.
Garbino, G.S.; Tavares, V.D.C. 2018. Roosting ecology of Stenodermatinae bats (Phyllostomidae): Evolution of foliage roosting and correlated phenotypes. Mammal Review, 48: 75-89.
Giannini, N.P.; Kalko, E.K. 2004. Trophic structure in a large assemblage of Phyllostomid bats in Panama. Oikos, 105: 209-222.
Giannini, N.P.; Kalko, E.K.V. 2005. The guild structure of animalivorous leaf-nosed bats of Barro Colorado Island, Panama, revisited. Acta Chiropterologica, 7: 131-146.
Hurtado, N.; Sepúlveda, R.; Pacheco, V. 2015. Sexual size dimorphism of a sensory structure in a monomorphic bat. Acta Chiropterologica, 17: 75-83.
Kerth, G. 2008. Causes and consequences of sociality in bats. Bioscience, 58: 737-746.
Koopman, K.F. 1978. Zoogeography of Peruvian bats with special emphasis on the role of the Andes. American Museum Novitates, 2651: 1-33.
Marinello, M.M.; Bernard, E. 2014. Wing morphology of Neotropical bats: a quantitative and qualitative analysis with implications for habitat use. Canadian Journal of Zoology, 92: 141-147.
Mello, M.A.R.; Pol, A. 2006. First record of the bat Mimon crenulatum (E. Geoffroy, 1801) (Mammalia: Chiroptera) in the state of Rio de Janeiro, Southeastern Brazil. Brazilian Journal of Biology, 66: 295-299.
Murcia-García, U.G.; Medina-Lozano, R.M.; Rodríguez-Rondón, J.M.; Hernández Anzola, A.M.; Herrera-Rodríguez, E.V. 2014. Monitoreo de los bosques y otras coberturas de la amazonia colombiana, a escala 1:100.000 -Datos del período 2012 1st ed. Instituto Amazónico de Investigaciones Científicas SINCHI, Bogotá, 144p.
Nassar, J.M.; Ramírez, M.N.; Linares, O. 1997. Comparative pollination biology of Venezuelan columnar cacti and the role of nectar-feeding bats in their sexual reproduction. American Journal of Botany, 84: 918-927.
Norberg, U.M.; Rayner, J.M. 1987. Ecological morphology and flight in bats (Mammalia; Chiroptera): wing adaptations, flight performance, foraging strategy and echolocation. Philosophical Transactions of the Royal Society B: Biological Sciences, 316: 335-427.
Novaes, R.; Souza, R.; Ribeiro, E.; Siqueira, A.; Greco, A.; Moratelli, R. 2015. First evidence of frugivory in Myotis (Chiroptera, Vespertilionidae, Myotinae). Biodiversity Data Journal, 3: e6841.
Pedro, W.A.; Komeno, C.A.; Taddei, V.A. 1994. Morphometrics and biological notes on Mimon crenulatum (Chiroptera, Phyllostomidae). Boletim do Museu Paraense Emílio Goeldi, 10: 107-112.
Rojas-Martínez, A.E.; Pavón, N.P.; Castillo, J.P. 2015. Effects of seed ingestion by the lesser long-nosed bat Leptonycteris yerbabuenae on the germination of the giant cactus Isolatocereus dumortieri The Southwestern Naturalist, 60: 85-89.
Saldaña-Vázquez, R.A.; Castaño, J.H.; Baldwin, J.; Pérez-Torres, J. 2019. Does seed ingestion by bats increase germination?: a new meta-analysis 15 years later. Mammal Review, 49: 201-209.
Santiago-Hernández, M.H.; Martén-Rodríguez, S.; Lopezaraiza- Mikel, M.; Oyama, K.; González-Rodríguez, A.; Quesada, M. 2019. The role of pollination effectiveness on the attributes of interaction networks: from floral visitation to plant fitness. Ecology, 100: e02803.
Sikes, R.S.; Gannon, W.L.; The Animal Care and Use Committee of the American Society of Mammalogists. 2016. Guidelines of the American Society of Mammalogists for the use of wild mammals in research and education. Journal of Mammalogy, 97: 663-688.
Solari, S. 2019. Mimon crenulatum The IUCN Red List of Threatened Species: e.T13560A22105694 (T13560A22105694 (https://www.iucnredlist.org/species/13560/88177260 ). Accessed on 20 Jul 2021.
» https://www.iucnredlist.org/species/13560/88177260
Soriano, P.J.; Ruiz, A. 2002. The role of bats in reproduction of columnar cacti in the northern Andes. In: Fleming, T.H.; Valiente-Banuet, A. (Ed.). Ecology, Evolution and Conservation of Columnar Cacti and Their Mutualists (241-263) Arizona University Press, Tucson, p.241-263.
Tirira, D.G. 2017. A Field Guide to the Mammals of Ecuador 1st ed. Editorial Murciélago Blanco, Quito, 600p.
Voss, R.S.; Fleck, D.W.; Strauss, R.E.; Velazco, P.M.; Simmons, N.B. 2016. Roosting ecology of amazonian bats: evidence for guild structure in hyperdiverse mammalian communities. American Museum Novitates, 3870: 1-44.
Wilson, D.E. 1973. Bat faunas: a trophic comparison. Systematic Zoology, 22: 14-29.
Williams, S.; Genoways, H. 2008. Subfamily Phyllostominae. In: Gardner, A.L. (Ed.). Mammals of South America. v.I. Marsupials, Xenarthrans, Shrews and Bats The University of Chicago Press., Chicago, 669p.

CITE AS:

Castillo-Figueroa, D.; Tarrá-Jaramillo, B.A.; Peñuela-Salgado, M.M.; Giraldo-Martínez, C.A.; Rodríguez-León, C.H. 2022. First evidence of frugivory in Gardnerycteris crenulatum (Chiroptera: Phyllostomidae). Acta Amazonica 52: 38-41.

Edited by

ASSOCIATE EDITOR:

Paulo D. Bobrowiec

Data availability

Data citations

ASM. 2021. Mammal Diversity Database, Version 1.6. American Society of Mammalogists. ( (https://www.mammaldiversity.org/taxa.html ). Accessed on 08 Oct 2021.

Publication Dates

Publication in this collection
16 Mar 2022
Date of issue
Jan-Mar 2022

History

Received
20 July 2021
Accepted
06 Dec 2021

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] Aranguren, C.I.; González-Carcacía, J.A.; Martínez, H.; Nassar, J.M. 2011. Noctilio albiventris (Noctilionidae), a potential seed disperser in disturbed tropical dry forest habitats. Acta Chiropterologica, 13: 189-194.

[2] ASM. 2021. Mammal Diversity Database, Version 1.6. American Society of Mammalogists. ( (https://www.mammaldiversity.org/taxa.html ). Accessed on 08 Oct 2021.
» https://www.mammaldiversity.org/taxa.html

[3] Bernard, E.; Fenton, M.B. 2003. Bat mobility and roosts in a fragmented landscape in central Amazonia, Brazil. Biotropica, 35: 262-277.

[4] Castillo-Figueroa, D. 2020a. Ecological morphology of neotropical bat wing structures. Zoological Studies, 59: e60.

[5] Castillo-Figueroa, D. 2020b. Why bats matters: a critical assessment of bat-mediated ecological processes in the Neotropics. European Journal of Ecology, 6: 77-101.

[6] Emmons, L.H.; Feer, F. 1999. Mamíferos de Los Bosques Húmedos de América Tropical, una Guía de Campo 1st ed. Editorial FAN, Santa Cruz de la Sierra, 298p.

[7] Fleming, T.H. 1986. Opportunism versus specialization: the evolution of feeding strategies in frugivorous bats. In: Estrada, A.; Fleming, T.H. (Ed.). Frugivores and Seed Dispersal Springer, Dordrecht, p.105-118.

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